WO2018029145A1 - Method for checking the plausibility of the ascertained compression of an internal combustion engine - Google Patents

Abstract

The invention describes a method for checking the plausibility of a sensor signal which is indicative of a compression of an internal combustion engine, wherein the compression can be variably adjusted by means of an actuator depending on an actuating variable. The method comprises the following: (a) ascertaining (110) a series of corresponding values of the sensor signal and values of the actuating variable, (b) determining (120) a relationship between the sensor signal and the actuating variable based on the ascertained series of corresponding values of the sensor signal and of the actuating variable, (c) determining (130) a deviation between the determined relationship and a predetermined characteristic relationship between the sensor signal and the actuating variable, and (d) determining (140) that the sensor signal is plausible when the determined deviation is lower than a predetermined threshold value. The invention further describes an engine controller and a computer program.

Description

description

Method for checking the plausibility of the determined compression of an internal combustion engine

The present invention relates to the technical field of internal combustion engines. In particular, the present invention relates to a method for plausibility checking of a sensor signal that is indicative of a compression of an internal combustion engine, wherein the compression by means of an actuator in dependence on an Aktuierungsgröße is variably adjustable. The present invention also relates to a motor controller and a computer program. In internal combustion engines with variable compression, as described for example in DE 10 2012 008 244 AI, engine damage and negative impact on the exhaust can occur if the actual compression does not correspond to the desired compression. The variable compression is usually controlled by a closed-loop control system, where a sensor signal indicative of compression is used as the feedback signal to control an actuation quantity for an actuator with which the compression is adjusted. The present invention is based on the object a determined via such a sensor signal compression to reasonableness ^¬ taping.

This object is solved by the subject matters of the independent claims. Advantageous embodiments of the vorlie ^¬ constricting invention are described in the dependent claims.

According to a first aspect of the invention, a method is described for checking the plausibility of a sensor signal, which is indicative of a compression of an internal combustion engine, wherein the compression by means of an actuator is variably adjustable as a function of an actuation variable. The described method comprises: (a) determining a series of (b) determining a relationship between the sensor signal and the Aktuierungsgröße based on the he ^¬ mediated series of corresponding values of the sensor signal and the Aktuierungsgröße, (c) determining a deviation between the particular context and a predetermined characteristic relationship between the sensor signal and the amount of actuation; and (d) determining that the sensor signal is plausible if the determined deviation is less than a predetermined threshold.

The method described is based on the finding that the actuator geometriebedingt must perform a certain work when a certain compression is set, as in each compression (with the same load) a corresponding

Counteracting force acts on the piston due to the combustion, which must be counteracted by the actuator to maintain the compression. When the sensor signal of the actual compression corresponds, therefore, the relationship between the sensor signal and the Aktuierungsgröße in ^¬ sentlichen We must be equal to a predetermined relationship.

According to the invention, a number of corresponding (or pairwise belonging) values of the sensor signal and values of the actuation quantity are determined. Based on he ^¬ mediated series (for example by interpolation) a relationship between the sensor signal and the Aktuierungsgröße is then determined. A deviation between this particular relationship and a predetermined characteristic relationship between the sensor signal and the actuation quantity is then determined. As long as the determined deviation is less than a predetermined threshold, the sensor signal is considered plausible, that is, it can be assumed that the actual compression is equal to or sufficiently close to the compression expected based on the sensor signal, and thus neither engine damage nor a negative impact on the exhaust will occur. According to an embodiment of the invention, the Ver ^¬ drive further comprises: (a) determining, based on the determined relationship between the sensor signal and the Aktuierungsgröße, a value of the sensor signal, wherein the corresponding value of Aktuierungsgröße has an extremum, (b) Determining, based on the predetermined characteristic relationship between the sensor signal and the amount of actuation, a reference value of the sensor signal at which the corresponding reference value of the actuation quantity has an extremum, and (c) determining the deviation as a deviation between the determined value of the sensor signal and the determined one Reference value of the sensor signal.

In other words, the value of the sensor signal is determined in which the corresponding value of the actuation variable has an extreme, in particular a maximum or a minimum, according to the specific relationship. Furthermore, a reference value of the sensor signal is determined in which the corresponding value of the actuation variable has an extreme, in particular a maximum or a minimum, in accordance with the predetermined characteristic relationship. The deviation is then determined as the deviation between the determined value of the sensor signal and the determined reference value of the sensor signal. The deviation thus represents a difference between the actual value of the sensor signal and the reference value of the sensor signal, in which case the corresponding value of the actuation variable has an extremum. If the respective extremes occur at different values of the sensor signal, the sensor signal does not represent a plausible indicator for the compression.

According to one embodiment of the invention, the

Internal combustion engine, a multi-joint crank drive with an eccentric shaft, wherein the actuator is arranged for rotating the eccentric shaft about its axis and wherein the sensor signal is output from a sensor which is adapted to detect the rotational angle of the eccentric shaft. In other words, the compression of the internal combustion engine is determined by adjusting the rotation angle of the eccentric shaft. The angle of rotation is set by the actuator as a function of the actuator size.

According to a further embodiment of the invention, the actuator is an electromechanical actuator and the Aktuierungsgröße is an electric current. The electromechanical actuator, for example an electric motor, is set up to adjust the compression as a function of the current intensity of the supplied electric current. For example, the electromechanical actuator may be configured to rotate an eccentric shaft about its axis. The Actuate size is then the current that is required to hold a certain angle of rotation for the eccentric shaft and thus a certain compression in the internal combustion engine. The electric current can thus also be referred to as holding current.

According to a further embodiment of the invention, the actuator is a hydraulic actuator and the Aktuierungsgröße is a hydraulic pressure. The hydraulic actuator is adapted to, in the special ^¬ a liquid to adjust the compression in dependence on the pressure of a hydraulic fluid. The hydraulic actuator can be configured for example to a Exzen ^¬ shaft is engaged to rotate about its axis. The Aktuierungsgröße is then the hydraulic pressure that is required to hold a certain angle of rotation for the eccentric shaft and thus a certain compression in the internal combustion engine. The hydraulic pressure can thus also be referred to as holding pressure. According to a further embodiment of the invention, the number of corresponding values of the sensor signal values and the Aktuierungsgröße during a measurement process is systematically it averages ^¬. By "systematically determined", it is understood in the present context that the series of corresponding values are determined to undergo a series of compression (at a constant load) settings, with the value of the sensor signal and the value at each individual setting For example, such a series of compaction settings may include regularly spaced values between a minimum settable compaction and a maximum settable compaction (or vice versa) Alternatively, the series of compaction settings may have a number of settings In accordance with a further embodiment of the invention, the series of corresponding values of the sensor signal and values of the actuation quantity during operation are determined within a predetermined time window Embodiment finds the determination of ent ^¬ speaking values of the sensor signal and the Aktuierungsgröße during normal operation of the internal combustion engine. The predetermined time window is selected so that a sufficient number of compression settings (for the same load) are used so that a suitable series of corresponding values can be determined.

According to a further embodiment of the invention, the method further comprises correcting the predetermined characteristic relationship between the sensor signal and the

Compaction based on the determined deviation when the determined deviation is between the predetermined threshold and another threshold. In other words, the predetermined characteristic relationship between the value of the sensor signal and the compression is recalibrated if the determined deviation between the threshold values, that is, in a predetermined Area, lies. Consequently, it can be assumed after the calibration that the deviation is again below the threshold value.

According to another embodiment of the invention, the method further comprises outputting an error message if the determined deviation exceeds the further threshold value.

If the deviation is too large, an error message is output according to the invention. The error message can then (possibly in combination with other circumstances) lead to a continuation of travel being restricted or even impossible.

In accordance with a second aspect of the invention, an engine control system for a vehicle configured to use a method according to the first aspect and / or one of the above embodiments is described.

This engine control makes it possible in a simple manner to plausibilize a sensor signal that is indicative of the compression of an internal combustion engine.

According to a third aspect of the invention, a computer program is described which, when executed by a processor, is adapted to perform the method according to the first / second aspect and / or one of the above embodiments.

For the purposes of this document is the mention of such Com ^¬ computer program equivalent to the concept of a Pro ^¬ program element, a computer program product and / or a computer-readable medium containing instructions for controlling a computer system to the operation of a system or a method in to coordinate suitably to achieve the effects associated with the method according to the invention. The computer program may be implemented as a computer-readable instruction code in any suitable programming language such as JAVA, C ++, etc. The computer program can be stored on a computer-readable storage medium (CD-ROM, DVD, Blu-ray Disc, removable drive, volatile or non-volatile memory, built-in memory / processor, etc.). The instruction code may program a computer or other programmable device such as, in particular, an engine control unit of a motor vehicle to perform the desired functions. Further, the computer program may be provided in a network, such as the Internet, from where it may be downloaded by a user as needed. The invention can be realized both by means of a computer program, ie a software, and by means of one or more special electrical circuits, ie in hardware or in any hybrid form, ie by means of software components and hardware components.

It should be noted that embodiments of the invention have been described with reference to different subject ^{matters ¬} . In particular, some embodiments of the invention are described with method claims and other embodiments of the invention with apparatus claims. the

However, one skilled in the art, upon reading this application, will readily appreciate that, unless explicitly stated otherwise, in addition to a combination of features associated with a type of subject matter, any combination of features that may result in different types of subject matter is also possible belong.

Further advantages and features of the present invention will become apparent from the following description of a preferred embodiment. FIG. 1 shows a flow chart of a method according to the invention.

FIG. 2 shows an illustration of several rows of corresponding values of a sensor signal and an actuation variable, which were determined in connection with a method according to the invention.

Figure 3 shows a sectional view of a Mehrgelenkkur- accessory with eccentric shaft with which the inventive

Method can be used.

It should be noted that the embodiments described below represent only a limited selection of possible embodiments of the invention.

1 shows a flow diagram 100 of a method according to the invention for plausibility checking of a sensor signal (for example a rotation angle sensor signal) indicative of the compression of an internal combustion engine, wherein the compression by means of an actuator (for example an electric motor) in dependence on a Aktuierungsgröße (for example a current) is variably adjustable.

At 110, a series of corresponding values of the sensor signal and values of actuator size are determined. This can be done, for example, in a systematic measurement process in which a series of values of compaction is predetermined and the resulting values of the sensor signal and the Aktu ^¬ ierungsgröße are determined and stored. Alternatively, the corresponding (pairwise related) values may be sequentially acquired in normal operation until the required set of values has been collected.

After the series has been determined, at 120, a relationship between the sensor signal and the actuation quantity is based on the determined series of corresponding values of the sensor signal and the Aktuierungsgröße determined.

At 130, the deviation (eg, a shift or difference) between the determined relationship and a predetermined characteristic relationship between the sensor signal and the actuation quantity is then determined. The ^predefined characteristic relationship here denotes the expected relationship between the sensor signal and the actuation quantity. The deviation can be determined in a more specific example as follows:

Based on the specific relationship between the sensor signal and the Aktuierungsgröße the value Wmax of the sensor signal is determined, in which the corresponding value of Aktuierungsgröße an extremum, for example, a maximum ^¬ has. The value Wmax is therefore based ultimately on which he ^¬ mittelte set of values of the sensor signal and the Aktuie ^¬ approximate size.

Then but is similarly determined based on the predetermined characteristic relating a reference value Wmax_ref of the sensor signal, wherein the corresponding ^¬ Refe rence value of Aktuierungsgröße an extremum, for example, has a maximum. The value Wmax_ref thus denotes the value of the sensor signal at which the extremum is to be expected.

Now, the deviation is determined as the deviation between the value Wmax and the reference value Wmax_ref, for example, as the absolute difference of the two values.

At 135, the determined deviation is compared with a threshold S and, in particular, it is determined whether the determined deviation is greater or less than the threshold S.

If it is determined at 135 that the deviation is less than the threshold S, then it is concluded at 140 that the sensor signal is plausible. That is, the sensor signal delivers plausible statements about the compression in the internal combustion engine.

If instead it is determined at 135 that the deviation is not less than the threshold S, then at 150 either a correction is made or an error message is issued. Whether a correction is to be made or an error message is to be issued can be decided, for example, depending on whether the deviation is greater or less than another threshold value. The further threshold is greater than the threshold S. If the deviation between the two thresholds, a correction can be made, for example, the relationship between the value of the sensor signal and the associated compression can be corrected to compensate for the deviation. This corresponds to a recalibration of the sensor. If the deviation also exceeds the further threshold value, an error message is output instead. The error message then has the consequence that a continuation of travel is restricted (with lower engine power) or not at all possible.

FIG. 2 shows an image 200 of a plurality of rows 210, 220, 230, 240, 250 of corresponding values of a sensor signal DW and an actuation variable I, which were determined in connection with a method according to the invention, for example in method step 110 in the figure described above 1. here, the sensor signal DW measures the output signal from a rotational angle sensor ^¬ that the angle of rotation of an eccentric shaft in an articulated crank mechanism (such as that described below in connection with Figure 3). The actuation size I is the

Amperage, which must be supplied to an electromechanical actuator (electric motor), so that the rotation angle of Ex ^{¬ center} shaft can be held. In other words, I is the current at which the actuator can compensate for the torque acting on the eccentric shaft due to the combustion in the internal combustion engine. The curve 210 represents a series of corresponding rotation angles DW and currents I determined at a low load. Curve 220 represents a series of corresponding angles of rotation DW and currents I determined at a medium load. The curve 230 represents a series of corresponding rotation angles DW and currents I determined at a higher load. The three curves 210, 220, 230 all reach the respective maximum current 212, 222, 232 (extremum) at a rotation angle DW of 90 °. In the present case, this rotation angle corresponds to the reference value at which the compression should actually be maximum. It can thus be concluded that the sensor signals 210, 220, 230 are plausible.

The situation is different for curves 240 and 250. Both curves represent a series of corresponding angles of rotation DW and currents I which were determined at the same average load as curve 220. As can be clearly seen, the maximum current 242 for the curve 240 is at a rotation angle of about 85 ° and the maximum current 252 for the curve 250 is at a rotation angle of about 95 °. The curve 240 thus corresponds to a positive offset value of + 5 ° and the curve 250 corresponds to a negative offset value of -5 °, which (as explained above in connection with FIG. 1) is either corrected (by recalibration) or gives rise to an error message can give.

FIG. 3 shows a sectional view of a multi-joint crank drive 300 with eccentric shaft 332, with which the above-described method 100 according to the invention can be used. The multi-joint crank drive 300 is known as such and consists of a coupling member 310, which is connected via pivot 312 with Kolbenpleuel 320 and piston 322 and via pivot 314 with Anlenkpleuel 330. The Anlenkpleuel 330 is rotatably supported about the eccentric shaft 332, which can be rotated by means of an actuator (not shown) about the eccentrically mounted axis of rotation 334 to adjust the compression (by displacement of the piston in (not shown) cylinder). Of the Rotation angle of the eccentric shaft is detected by a suitable (not shown) rotation angle sensor, for example, an optical or mechanical rotation angle sensor. When the internal combustion engine is in operation, the actuator must apply a torque to the eccentric shaft 332, which compensates the torque applied by the operating internal combustion engine to the eccentric shaft 332, so that the set rotational angle of the eccentric shaft is held. This fact, as described above by the plausibility-checking method according to the invention, uses the output signal from the rotation-angle sensor as an indication for the compression.

Reference sign list

100 flowchart

 110 process step

120 process step

130 process step

135 process step

140 process step

150 process step

200 illustration

 210 curve

 212 maximum

 220 curve

 222 maximum

 230 curve

 232 maximum

 240 curve

 242 maximum

 250 curve

 252 maximum

 DW rotation angle

 I current

 300 multi-link crank drive

310 coupling member

 312 swivel joint

 314 swivel joint

 320 piston connecting rods

 322 pistons

 330 Anlenkpleuel

 332 eccentric shaft

 334 axis of rotation

 340 crankshaft

Claims

claims A method for plausibility checking of a sensor signal which is indicative of a compression of an internal combustion engine, wherein the compression by means of an actuator in dependence on an Aktuierungsgröße is variably adjustable, comprising the method  Determining (110) a series of corresponding values of the sensor signal and values of the actuator size, Determining (120) a connection between the Sen ^¬ sorsignal and Aktuierungsgröße based on the determined set of corresponding values of the sensor signal and the Aktuierungsgröße,  Determining (130) a deviation between the determined relationship and a predetermined characteristic relationship between the sensor signal and the amount of actuation and  Determining (140) that the sensor signal is plausible if the determined deviation is less than a predetermined one Threshold is. 2. A method according to the preceding claim, further comprising  Determining, based on the determined relationship between the sensor signal and the actuation quantity, a value of the sensor signal at which the corresponding value of the actuation variable has an extremum,  Determining, based on the predetermined characteristic relationship between the sensor signal and the actuation variable, a reference value of the sensor signal in which the corresponding reference value of the actuation variable has an extremum, and  Determining the deviation as a deviation between the determined value of the sensor signal and the determined reference value of the sensor signal. 3. The method according to claim 1 or 2, wherein the internal combustion engine is a multi-joint crank mechanism with an Exzen- terwelle, wherein the actuator is arranged to rotate the eccentric shaft about its axis and wherein the sensor signal is output from a sensor which is adapted to detect the angle of rotation of the eccentric shaft. 4. The method according to any one of the preceding claims, wherein the actuator is an electromechanical actuator and wherein the Aktuierungsgröße is an electric current. 5. The method according to any one of claims 1 to 3, wherein the actuator is a hydraulic actuator and wherein the Aktuierungsgröße is a pressure. 6. The method according to any one of the preceding claims, wherein the series of corresponding values of the sensor signal and values of Aktuierungsgröße is determined systematically during a measuring operation. A method according to any one of claims 1 to 4, wherein the series of corresponding values of the sensor signal and values of the actuation quantity during operation are determined during a predetermined time window. 8. The method of claim 1, further comprising correcting the predetermined characteristic relationship between the sensor signal and the compression based on the determined deviation when the determined deviation is between the predetermined threshold and another threshold. 9. The method of claim 1, further comprising outputting an error message if the determined deviation exceeds the further threshold. A motor controller for a vehicle configured to use a method according to any one of the preceding claims A computer program which, when executed by a processor, is arranged to perform the method of any one of claims 1 to 9.